BE1028417A1 - FIBER PLANT PROCESSING MACHINE - Google Patents

Abstract

The invention relates to a processing machine for turning over harvested flax placed on a ground, the processing machine comprising a vehicle and a processing installation for processing flax. The installation comprises a pivotable support unit, a rotatable pick-up element arranged at the free end of the pivotable support unit for picking up flax harvested and placed on the ground, a conveyor for transporting the collected flax and finally a delivery unit for placing it on the ground. laying down hot flax. The pivotable support unit further comprises at least one rotatable support wheel located at an axial position behind the rotatable pick-up element and at a lateral position adjacent to the rotatable pick-up element.

Description

FIBER PLANT PROCESSING MACHINE The invention relates to a processing machine for processing fiber plants, such as hemp or flax.

More particularly, the invention relates to a fiber plant turner for picking up and turning over harvested and planted fiber plants and to a fiber plant reel for picking and coiling fiber plants placed on the substrate.

Flax, in particular fiber flax, is a crop that is grown for making linen, among other things.

The flax plant is usually between 80 and 120 cm tall and is harvested by pulling it out of the ground.

The harvested flax plant is not immediately removed from the substrate.

The flax is first laid flat on the ground in long rows, also called "swaths", with the stems of the harvested flax plants extending substantially transversely to the longitudinal direction of the swaths.

This laying the flax back flat on the ground so that the said swaths are formed is also called "wearing out" or "plucking".

When laying the flax plants in rows or swaths, a gap is left between adjacent rows.

These spaces are provided to prevent the swaths from becoming entangled.

The flax plants harvested and swathed flat on the substrate are then rooted under the influence of a combination of dew, rain and sunlight.

The rotting of the flax by leaving the flax plants on the substrate (ie a field or root field) for some time (approx. 2 weeks, depending of course on the weather conditions (humidity, amount of sunlight, etc.) processing flax is called field rot or dew rot.

To obtain an even rotting and to prevent the flax from rotting, the flax laid flat in strips on the substrate must be turned over regularly.

This turning over of the flax placed flat on the ground is also called "turning".

The turning of the flax is carried out with a special machine for processing flax.

Such a machine is known as a (flax) turner or turning machine and typically comprises a pivotable support beam at the free end of which is arranged a rotating pick-up drum with a support wheel placed in front of it.

The rotating pick-up drum is guided along the flax and picks up the lying flax.

Such a turning machine may also comprise a reversing conveyor for transporting and simultaneously reversing the picked up flax and a delivery unit with which the picked up, transported and turned over flax is laid flat on the ground again.

During turning, the flax can possibly be deseeded, which is called "turning strips".

The seed bulbs are removed from the stems of the flax.

Once the retting is sufficient, the flax is picked up from the substrate and, if necessary, rolled up and pressed for further processing. The flax is picked up and rolled up (and possibly deseeded) using winding machines. A winding machine typically has a similar pivoting support boom and rotating pick-up drum to the turning machine, but has a conveyor that transports the picked flax only to the rear of the vehicle without turning the flax over. A roll-up mechanism is also provided for rolling up the flax and placing the (rolled) flax on the surface.

The turning machines and/or winding machines described above for turning and winding up the fiber plants laid in rows or swaths respectively are available in many different designs and types. In a certain type of turning machine or winding machine there is a vehicle that has been specially developed to be able to drive over the rows or swaths of flax and thereby be able to pick up the flax, turn it over / roll it up and put it down. In other types of turning machines or winding machines, the vehicle is provided with its own drive to move the vehicle, but the vehicle is pulled by another vehicle, for instance a tractor or a similar agricultural vehicle.

In the known turning or winding machines, some of the wheels of the vehicle are spaced apart such that the wheels drive in the spaces between the rows of flax and thus do not drive over the flax itself. In some types of turning and winding machines, however, there are also one or more wheels that drive over the flax itself. This may be a (transport) wheel of the vehicle itself, but may also be support wheels of the pivotable support beam. Such a support wheel is located in front of the pick-up drum in the axial direction of displacement of the vehicle and in transverse direction at the location of the row of flax. In other words, while driving, the support wheel will drive over the fibrous plants that have not yet been collected. This can damage the fiber plants by the support wheel before the pick-up drum has had a chance to pick up the flax. The wheel presses on the fiber plant with essentially the load of the entire support tree. It has been found that as a result there is a risk that the fiber is detached from the wood structure (bark) of the fiber plant and the quality of the fiber plant deteriorates. This is especially the case with fiber plants that have been turned over one or more times before.

A further drawback of the known turning machines and winding machines is that the support wheel is located at a fairly large distance in front of the pick-up drum. This large distance is necessary to prevent the pick-up drum from trying to pick up fiber plants, one end of which is still under the support wheel. It has been found, however, that the great distance may mean that the pick-up drum arranged behind the support wheel does not always accurately follow the unevenness in the ground. The consequence of this is that either the fiber plants can then be picked up less well by the pick-up drum, for example in potholes in the subsoil, or that the pick-up drum has a tendency to pick up more than the fiber plants, such as soil, as with knolls in the surface. The latter would mean that the fiber plants transported by the conveyor would become contaminated with soil and mud. In order to prevent contamination, the support of the support beam by the support wheel is often adjusted in the case of a surface with relatively large unevennesses, such that the pick-up drum is located a lot higher above the surface. This does mean a loss of fiber plants, since part of the fiber plates then remains behind on the substrate. As a result, the yield of the field decreases.

It is an object of the invention to provide an improved processing machine for processing fiber plants, in which one or more of the drawbacks of the prior art are at least partially obviated.

It is also an object of the invention to provide a processing machine in which the risk of damage to the fiber plants during processing is reduced.

It is a further object to provide a processing machine with improved driving characteristics.

Finally, it is an object to provide a processing machine with which the ground can be followed better.

At least one of these and/or other objects is achieved at least in part in a processing machine for processing fiber plants, wherein the processing machine comprises: - a self-propelled or towed vehicle, comprising a chassis having mounted thereon: - a first and second rear wheel positioned at substantially equal or different positions in the axial direction and at laterally different, spaced positions, the lateral direction extending transversely to the axial direction; - a front wheel positioned in a lateral direction substantially the same as the first rear wheel, wherein the front wheel is of pivotable design; - a processing installation for picking up and transporting the fiber plants, the processing installation comprising: - a pivotable support unit attached to the rear of the chassis and extending forwards, in particular a pivotable support boom; - a rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the substrate; - a conveyor for transporting the picked fiber plants from the pick-up element in axial direction to the rear of the self-propelled vehicle; wherein the pivotable support unit comprises at least one rotatable support wheel for supporting the support unit on the ground, wherein the rotational axis of the at least one support wheel is located at an axial position behind the rotational axis of the rotatable pick-up element and the at least one support wheel is located at a lateral position next to the rotatable pick-up element.

By positioning the rotatable support wheel behind the rotatable pick-up element, when the vehicle is driving over the ground, the flax will first be picked up by the pick-up element. Only after this will the one or more rotatable support wheels (whereby a rotatable support wheel can also be a support roller) touch the ground. The flax to be picked up therefore does not experience any hindrance from the rotatable support wheel, which reduces the risk of damage to the flax, for instance the seed in the flax. In addition, the at least one rotatable support wheel is located at a lateral position adjacent to the side of the rotatable pick-up element. This has a number of advantages, as will be explained later.

The axial distance between the axis of rotation of the at least one support wheel and the axis of rotation of the pick-up element is preferably at least 5 cm. Even more preferably, this distance is between 5 cm and 50 cm. If there is too little distance between them, there is a risk that a support wheel will press a stem of a fiber plant onto the substrate before the drum has picked up this stem. If there is too much intermediate distance, the pick-up element can insufficiently follow the ground, especially in the case of a ground with large unevennesses. Furthermore, the lateral distance between the sides of the pick-up element facing each other on the one hand and a support wheel on the other hand is between 1 cm and 50 cm.

The processing machine may be a fiber plant turner, such as a flax turner, or a fiber plant roll up machine, such as a flax turner. In certain embodiments, the processing machine is both a turning machine and a winding machine, for example when a partly or wholly interchangeable processing installation is used.

In embodiments where the processing machine is a turning machine for turning over harvested fiber plants placed on a substrate, the processing installation comprises a pick-up and turning installation for picking up, turning and laying fiber plants. The pick-up and turning installation can then, for example, include the pivotable support unit attached to the rear of the chassis and extending forwards, the rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the ground as well as the conveyor for transporting the picked fiber plants from the pick-up element in axial direction to the rear of the vehicle. The conveyor is herein designed to turn the collected fiber plants during transport. The pick-up and turning installation may further comprise a delivery unit provided at the rear of the vehicle, which is adapted for depositing the inverted fiber plants on the ground.

In certain embodiments in which the processing installation is a roll-up machine for rolling up fiber plants placed on a substrate into a roll, the processing installation comprises a pick-up and roll-up installation for picking up, rolling up and laying down the fiber plants. The pick-up and roll-up installation can then accommodate the pivoting support unit mounted at the rear of the chassis and extending forwards, the rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the ground, and the conveyor for transporting the picked fiber plants from the pick-up element in axial direction to the rear of the self-propelled vehicle. Furthermore, a winding unit can be provided which is designed for rolling up the transported fiber plants into a roll and depositing the fiber plants arranged in a roll on the substrate.

In further embodiments, the first and second rear wheels are positioned at a substantially equal position in the axial direction. Furthermore, in certain embodiments, the vehicle has only three wheels and thus forms a tricycle. For example, when in certain embodiments the front wheel is positioned in a lateral direction substantially the same as the first rear wheel, the vehicle in fact has an asymmetrical undercarriage and thereby forms an asymmetrical tricycle. Such asymmetry has consequences for the weight distribution and for the associated driving characteristics of the vehicle. However, the asymmetry does provide space for the support unit next to the front wheel. The free end of the support unit is preferably on the opposite side to where the front wheel is located and even more preferably approximately next to the driver's cab. This provides the driver with an unobstructed view of the pick-up unit and the support wheels. The support unit is then preferably located at a lateral position between the lateral positions of the left and right rear wheels, but this need not be the case. It is, for example, in principle possible for the support unit to be aligned (axially) with the lateral position of the second rear wheel.

In particularly advantageous embodiments, the processing installation of the processing machine comprises two or more rotatable supporting wheels attached side by side to the pivotable support unit. By using two or more rotatable support wheels next to each other, the support unit can be pushed more stably, so that less torsion generally occurs in the support wheel and possibly in the support unit during driving. Furthermore, a more even weight distribution can be achieved with two or more support wheels than with only one support wheel. Also, the driving characteristics are generally better than when only one support wheel or roller is used. It is also easier to create a relatively wide (joint) width of the wheels, which affects the driving and/or turning properties of the vehicle (turning properties in the sense of turning the vehicle when this is the end of a row of flax plants). achieved) will benefit.

As already described above, the rotatable support wheel is located in a lateral position adjacent to the side of the rotatable pick-up element. Similarly, when using two or more rotatable support wheels side by side, it may be preferable to provide at least one support wheel on each lateral side of the rotatable pick-up element. In addition to a stable support for the support unit (e.g. the support beam), this embodiment also offers the option of having the support wheels or support rollers roll over the above-mentioned interspaces present between adjacent rows of fiber plants. Furthermore, in principle two or more support wheels placed next to each other provide a better performance in the field of following unevenness in the subsoil, so that there is (even) less loss of fiber plants and/or less absorption of soil that could end up in the swath.

The one or more support wheels are attached to the support unit by one or more separate wheel suspension mechanisms. This wheel suspension can be designed such that the support wheels can passively steer along when the vehicle drives over the ground. This improves the vehicle's handling characteristics.

In further embodiments of the invention, height-adjusting means are provided for height-adjusting the free end of the pivotable support unit relative to the at least one support wheel. In practice this means an adjustment of the distance or clearance between the free end of the support unit and the ground and thus of the pick-up element with respect to the ground. Depending on the condition of the ground, the clearance between the pick-up element and the ground can thus be adjusted as desired. The height adjustment means preferably comprise a hydraulic actuator connected or connectable to a hydraulic system of the vehicle, such as a rotary actuator or a lifting cylinder. However, an electric actuator is also an option. In a particularly advantageous embodiment, the height adjustment can be controlled from the driver's cab of the vehicle, for instance while driving or when the vehicle has stopped for a while. This means that the driver does not have to get out to bring the pick-up element to the desired height for the relevant surface. This leads to an improvement in the efficiency of the turning operation, in particular in situations in which the subsoil shows relatively large irregularities.

In embodiments of the invention, the processing installation comprises a conveyor in the form of one of the pick-up and turning installations and a conveyor belt, wherein the position of the conveyor belt at the rear near the delivery unit is rotated through approximately 180 degrees with respect to the position of the conveyor belt. at the front near the rotatable pick-up element.

The conveyor is driven by a drive attached to the chassis of the vehicle. This drive can for instance be a hydraulic drive, but other types of drives are also possible.

The conveyor itself may be formed by one or more endless conveyor belts. These conveyor belts also engage the rotatable pick-up element and thereby drive the rotation of the pick-up element. However, a separate drive for the rotation of the pick-up element is also possible

Furthermore, the processing machine comprises a number of guide elements for guiding the collected fiber plants during transport towards the dispensing unit.

According to another aspect of the invention, there is provided a method of processing harvested fiber plants placed on a substrate, the method comprising driving the processing machine defined herein over a substrate and using the processing installation to pick up the fiber plants from the substrate, processing the fiber plants and subsequently depositing the processed fiber plants again on the substrate.

The can also include picking up the fiber plants from the subsoil with a pick-up and turning installation, then turning the collected fiber plants over and placing the inverted fiber plants back on the subsoil and/or removing the inverted fiber plants with a picking and rolling up installation. picking up the fiber plants, subsequently rolling up the picked fiber plants into a roll and placing the fiber plants rolled up into a roll again on the substrate.

Further advantages, features and details of the present invention will be elucidated from the following description of some embodiments thereof. In the description, reference is made to the attached figures.

Figure 1 shows a left side view of an embodiment of a processing machine, on a substrate; Figure 2 shows a front view of the embodiment of Figure 1; Figure 2A shows an enlarged view of the front view Figure 2; Figure 3 shows a right side view of the embodiment of Figures 1-4; Figure 3 shows a bottom view of the embodiment of Figure 1; Figure 4 shows a top view of the embodiment of Figure 1; Figures 5A and 5B show oblique views from below of a support beam according to the embodiment of Figures 1-4; Figure 5C shows a detail view of the connection of the support beam to the vehicle according to the embodiment of the preceding figures; and Figures 6A and 6B schematically show the mutual arrangement of the rotatable pick-up element and the support wheels, in a top view and a right side view, respectively.

Figure 1 shows an embodiment of a processing machine 1. The processing machine 1 comprises a three-wheeled vehicle 2 that drives over a ground (O) on which a number of parallel fiber plant rows (VR, only partially shown) of harvested fiber plants (V) are located. Each fiber plant row (VR) comprises a continuous layer of fiber plant stems that form an elongated mound on the bottom (substrate (O)). The stems of the fiber plants extend more or less parallel to each other and transverse to the longitudinal axis of the fiber plant row (VR) and thus transverse to the direction of travel of the processing machine 1. In the embodiment shown, the processing machine 1 is a turning machine, which means that the vehicle 2 is provided with a pick-up and turning installation.

3. This pick-up and turn-over installation is able to pick up the stems from the continuous layer of fiber plants at the front of the vehicle, then transport them to the rear of the vehicle and back onto the ground at the rear of the machine. to lay down. The path traveled backwards by the stems of the fiber plants during transport essentially describes a semi-spiral so that the stems are rotated about 180 degrees at the rear.

After harvesting, the pile of fiber plants is left on the substrate for a sufficient period of time for microorganisms present in the substrate to biologically degrade the fiber plant until the fiber plant is sufficiently degraded (i.e., rooted). The degree of biological degradation depends on the conditions in which the fiber plants are located, such as the humidity and the number of hours of sunshine to which the fiber plants are exposed. These conditions also vary according to whether the portion of the stem of the fibrous plant faces the substrate or the outside. Depending on the circumstances, the fiber plants must therefore be turned or turned over more or less often.

Figures 2-5 show the embodiment of Figure 1 in more detail. The figures show a processing machine 1 comprising a self-propelled vehicle 2 (i.e. a vehicle with a Cigen drive with which it can propel itself over a ground, also referred to herein as a self-propelled vehicle) to which a processing installation is arranged for processing flat on a underground fiber plants, such as flax plants, hemp plants and the like. In the embodiment shown, the processing installation 3 is a pick-up and turning installation 3 of a turning machine which is specifically designed for picking up harvested flax plants lying flat on the ground (ie the ground) from the ground, turning the flax plants over and put the flax plants back on the substrate. It will be clear to a person skilled in the art that instead of being self-propelled, the vehicle can also be of a type that can be pulled or pushed by another vehicle (not shown). Furthermore, it is clear to the skilled person that the processing installation can also be a pick-up and roll-up installation of a roll-up machine that is designed for picking up flax plants that may or may not have already been turned over, rolling the flax plants into a roll and placing them on the ground. of the flax plants arranged in a roll. Such roll-up machines are in principle identical to the aforementioned turning machines, with the exception of a slightly different design of the conveyor (after all, in the roll-up machine the conveyor only has to transport the fiber plants, without also requiring the turning of the fiber plants). In addition, the winding machine will first roll up the collected fiber plants before they are placed back on the substrate. For the sake of simplicity of the description, a separate treatment of the winding machine is therefore omitted in the following description of the figures.

The self-propelled vehicle 2 comprises a chassis 4 with three wheels, i.e. a right rear wheel 10, a left rear wheel 11 and a (right) front wheel 12. The chassis 4 is further provided with a driver's cabin 15 closed with glazing 19. In the embodiment shown, the driver's cab 15 is placed at the right-hand front of the chassis 3, so that the driver (not shown) has an optimal view of the ground in front of the cab (i.e. in axial direction (PA) or direction of movement of the vehicle 2) as well as on a number of crucial parts of the loading and turning installation 3 next to the cabin 15.

The driver can take a seat in the cabin 15 on a seat 16, which may or may not be separately sprung, and operate the vehicle 2 and the pick-up and turning installation 3 with the aid of control means. The control means can for instance comprise a steering wheel 17 for pivoting the front wheel 12, a number of pedals 18 for for instance controlling the drive of the rear wheels 10 and 11, a touch screen 13 for setting the pick-up and turning installation 3.

The pick-up and turning installation 3 comprises a pivotable support unit 20 secured to the rear of the chassis and a forwardly extending pivotal support unit 20. Referring to Fig. 5B, the pivotal support unit 20 is shown to have an elongate substantially axial direction (Pa). forwardly extending support beam 23 has at the free end 24 of which a rotatable pick-up element 60 is arranged. The support beam 23 has a lying fixing part 21 at the end opposite the free end 24. The lying fixing part 21 of the elongated support beam is connected via respective axes 51 and 53 of a left hinge 52 and a right hinge 54 to upright cheeks 48,49 of the chassis 4 of the vehicle 2. The hinges 52 and 54 make it possible to move the free end 24 of the support beam 23 and the rotatable pick-up element 60 attached thereto in upward and downward movement so that the pick-up element 60 can follow the ground over which the vehicle 2 travels. In the figures, and in particular in figure 5B, it is further shown that the support beam 23 is provided on the left front side with a protective bracket 101, to which bracket a number of flax guide elements 65 are arranged, with which the flax can be picked up better by the pick-up drum 60.

In certain embodiments, two support beams are provided side by side for picking up and turning two rows of fiber plants. In such embodiments it may be advantageous to design at least one of the support beams such that it can also be pivoted in lateral directions (Pi), so that the mutual distance of the pick-up elements can be adapted to the mutual distance of the rows of fiber plants.

In the embodiment shown, the pick-up element 60 is a pick-up drum (in other words, the pick-up element has substantially a cylindrical shape). The pick-up element 60 is designed to be rotatable about an (imaginary) rotation axis 95 (Figures 6A, 6B). In the situation shown in figures 6A, 6B, the axis of rotation is a horizontal axis extending transversely to the longitudinal direction of the vehicle 2 . Around the radial circumferential surface 96 of the pick-up drum, more specifically in the center thereof, is wound an endless conveyor belt 73 of the conveyor 69 to be described in more detail below, with which the pick-up drum is rotated about the substantially horizontal axis 95 . As indicated by an arrow (Ro) in Figure 5B, the pick-up drum 60 rotates in the opposite direction to the wheels of the vehicle 2. The rotational speed may vary, but is usually greater (e.g. 20-30% greater) than the rotational speed of the wheels of the vehicle.

Furthermore, two rows of projecting pins 611 and 612 are provided on the radial circumferential surface 96 of the pick-up drum 60, near both lateral side surfaces 97 and 98 thereof. The projecting pins extend from a common point, said common point being non-centric with respect to a center point of the pick-up drum.

This has resulted in the pins 611 and 612 projecting from the radial circumferential surface 96 when they are on the underside and front of the pick-up drum 60 and are wholly or partially retracted at other rotational positions of the pick-up drum 60. pins are therefore eminently suitable for picking up the (horizontally) lying stems of the fiber plants on the substrate and for lifting them from the substrate, while the fiber plants remain in the horizontal position.

The figures further show that the pick-up and turning installation 3 comprises a conveyor 69 for transporting the flax picked up at the front of the vehicle 2 by the rotating pick-up element 60 to the rear of the vehicle. In the embodiment shown, the conveyor 69 comprises a crossed endless conveyor belt 73 which is rotated by a rotating drive roller 81 at the rear of the vehicle. The upper part of the conveyor belt 73 moves in an axial direction from front to back (Pr, Fig. 5B). As shown in the figures, the position of the rear conveyor belt 73 near the dispensing unit 80 (to be described later) has been rotated approximately 180 degrees with respect to the front position of the conveyor belt 73 near the rotatable pick-up element 60. This As a result, the fiber plants which have been picked up from the ground by the pick-up element 60 in the lying position, essentially pass through a semi-helical shape during transport from the front to the back and are thus completely reversed. The stems of the fiber plants can now be placed on the substrate with the opposite side to the side on which the stems initially lay on the substrate, to promote an even rotation of the fiber plants.

The endless conveyor belt 73 of the conveyor 69 is driven by the aforementioned rotating drive roller 81 mounted at the rear on the chassis 4. In turn, the movement of the endless conveyor belt 73 drives the rotation (Ro, Fig. 5B) of the rotatable pick-up element. 60 on.

Finally, as indicated earlier, the pick-up and turning installation 3 comprises a delivery unit 80 arranged at the very rear of the chassis 4. This delivery unit 80 receives the flax picked up by the pick-up element 60 and the turned over flax conveyed by the conveyor 69 and guides it downwards in a controlled manner so that the reversed flax is neatly placed on the ground behind the vehicle 2. The dispensing unit 80 comprises a first and second endless conveyor belt 83, 84 which are both driven by the same drive roller 81. Both conveyor belts 83,84 are provided with projections 85 which support the flax in lying position when it is guided to the ground.

Figure SA shows that the pivotable support unit 20, in particular the free end 24 of the support beam 23 thereof, comprises two rotatable support elements in the form of a first support wheel 70 and a second support wheel 72. The support wheels 70, 72 are attached to the support beam via a suitable wheel suspension 71. Preferably, wheel suspension 71 is designed such that the wheels can steer along to some extent (passively), but a fixed wheel suspension is also an option.

The inventors have found that the positions of the two wheels 70,72 relative to the pick-up drum 60 have an unexpectedly great influence on the pick-up and transport process of the fiber plants. In the embodiment shown, the (imaginary or physical) rotation axes 96' and 96" of the left rotatable support wheel 70 and the right rotatable support wheel 72, respectively, are located in axial direction P1 behind the (imaginary or physical) rotation axis 95 of the rotatable pick-up element. 60. Furthermore, the radius (R70, R7) of each of the support wheels 70,72 is of the same order of magnitude or smaller than the diameter (R60) of the rotatable pick-up element 60. It is important that the respective contact surfaces 103 of the support wheels 70 72 with the substrate (O) are at the same axial position or, preferably, behind the contact surface 102 of the rotatable pick-up element 60 .

The positioning of the support wheels 70,72 ensures that when the vehicle 2 moves in the axial transport direction PA, the lying fiber plants are first picked up by the pick-up element 60 before they can come into contact with one or more of the support wheels 70,72. It has been found that damage to the flax can hereby be avoided and that picking up the flax and keeping it horizontal can be carried out better. The distance (d, see figures 6A,6B) over which the rotation axis 96,96" of the support wheels are located in the axial direction behind the rotation axis 95 of the pick-up element 60 can vary. At a distance of at least 5 cm (d > 5 cm) or preferably more than 20 cm, improved results can already be achieved Preferably the distance d is not too great, for example less than 50 cm, to ensure that the rotating pick-up element 60 can continue to follow the variations in the substrate well Furthermore, it is preferable that the lateral distance (ay) between facing sides of the pick-up element 60 (i.e. lateral side face 98) on the one hand and the left support wheel 70 on the other, and the lateral distance (ax) between facing sides of on the one hand the pick-up element 60 (ie lateral side surface 97) and on the other hand the right support wheel 72 between 1 cm and 50 cm By making the mutual distance in lateral direction PL of the support wheels 70,72 greater than the length of the pick-up drum 60, an improved stability of the support boom 23 during driving is achieved and also the pick-up process can be improved.

In the embodiment shown, the processing device 1 comprises height-adjusting means 101 for adjusting the height of the free end 24 of the pivotable support beam 23 relative to the at least one support wheel 70, 72 and thus the height of the rotatable pick-up element 60 attached to the support beam 23. relative to the ground (O). This actuator can be a hydraulic actuator, for example a linear or rotary actuator, which is coupled to the hydraulic system, to which the hydraulic drive of the rear wheels of the vehicle is also coupled. Furthermore, the wheel suspension of each of the support wheels 70,72 is designed to be able to steer in a passive manner for improving the driving characteristics of the processing machine.

The invention is not limited to the embodiments thereof described herein. The rights claimed are defined by the following claims, within the scope of which numerous modifications are conceivable.

Claims (22)

CONCLUSIONS Processing machine for processing fiber plants, in particular hemp or flax, the processing machine comprising: - a self-propelled or towed vehicle, comprising a chassis with mounted thereon: - a first and second rear wheel positioned on in axial direction substantially equal or different positions and at laterally different, spaced positions, the lateral direction extending transversely to the axial direction; - a front wheel which is designed to be pivotable; - a processing installation for picking up and transporting the fiber plants, the processing installation comprising: - a pivotable support unit attached to the rear of the chassis and extending forwards, in particular a pivotable support boom; - a rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the substrate; - a conveyor for conveying the picked fiber plants from the pick-up element in axial direction to the rear of the vehicle; wherein the pivotable support unit comprises at least one rotatable support wheel for supporting the support unit on the ground, wherein the rotational axis of the at least one support wheel is located at an axial position behind the rotational axis of the rotatable pick-up element and the at least one support wheel is located at a lateral position next to the rotatable pick-up element. A processing machine according to claim 1, wherein the processing machine is a turning machine for turning over harvested fiber plants placed on a substrate, the processing installation comprising a pick-up and turning installation for picking up, turning and laying down fiber plants, the picking and turning installation comprising: - the pivotable support unit attached to the rear of the chassis and extending forwards; - the rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the substrate; - a conveyor for conveying the picked-up fiber plants from the pick-up element in axial direction to the rear of the vehicle, the conveyor being configured to reverse the picked-up fiber plants during transportation; and - a delivery unit provided at the rear of the vehicle, designed for depositing the inverted fiber plants on the ground. Processing machine according to claim 1, wherein the processing machine is a winding machine for rolling up fiber plants placed on a substrate into a roll, the processing installation comprising a pick-up and roll-up installation for picking up, winding and laying down fiber plants, the pick-up and winding installation comprising: - the pivotable support unit attached to the rear of the chassis and extending forwards; - the rotatable pick-up element arranged at the free end of the pivotable support unit for picking up harvested fiber plants placed on the substrate; - a conveyor for transporting the picked fiber plants from the pick-up element in axial direction to the rear of the self-propelled vehicle; - a winding unit for rolling up the transported fiber plants into a roll and depositing the fiber plants arranged in a roll on the substrate. A processing machine according to any one of the preceding claims, wherein the first and second rear wheels are positioned at a substantially equal position in the axial direction. A processing machine according to any one of the preceding claims, wherein the front wheel is positioned in a lateral direction substantially the same as the first rear wheel. Processing machine according to one of the preceding claims, wherein the vehicle is a tricycle, in particular an asymmetrical tricycle. Processing machine as claimed in any of the foregoing claims, comprising two or more rotatable support wheels attached side by side to the pivotable support unit. Processing machine according to claim 6, comprising at least one support wheel on each lateral side of the rotatable pick-up element. Processing machine according to one of the preceding claims, wherein the axial distance between the axis of rotation of the at least one support wheel and the axis of rotation of the pick-up element is at least 5 cm, preferably between 5 cm and 50 cm. Processing machine according to one of the preceding claims, wherein the lateral distance between the sides facing each other of the pick-up element on the one hand and a support wheel on the other is between 1 cm and 50 cm. Processing machine as claimed in any of the foregoing claims, comprising height-adjusting means for height-adjusting the free end of the pivotable support unit relative to the at least one support wheel. Processing machine according to claim 11, wherein the height adjustment means comprise an electric linear actuator or a hydraulic actuator connected or connectable to a hydraulic system of the vehicle, for instance a linear or rotary actuator. Processing machine as claimed in any of the foregoing claims, comprising a passively co-steering wheel suspension for fastening the at least one support wheel to the support unit. Processing machine according to one of the preceding claims, wherein the conveyor of the processing installation comprises a conveyor belt, wherein when the processing installation is a pick-up and turning installation, the position of the conveyor belt at the rear near the dispensing unit is rotated through approximately 180 degrees with respect to of the position of the conveyor belt at the front near the rotatable pick-up element. Processing machine according to one of the preceding claims, comprising a drive for rotating the rotatable pick-up element, wherein the drive is preferably formed by the drive of the conveyor. Processing machine according to one of the preceding claims, comprising a number of guide elements for guiding the collected flax during transport towards the dispensing unit. Processing machine according to one of the preceding claims, wherein at least two processing installations are arranged side by side on the vehicle and wherein the support unit of at least one of the processing installations is also designed to be pivotable in the lateral direction. A processing machine according to any one of the preceding claims, wherein the rotatable pick-up element has a substantially cylindrical shape and comprises a plurality of protruding elements for picking up flax, the protruding elements extending from a common point, and the common point being non- is centric with respect to a center of the pick-up drum. Processing machine according to one of the preceding claims, wherein the radius of the at least one support wheel is of the same order of magnitude as or smaller than the radius of the rotatable pick-up element. A method for processing harvested fiber plants and placed on a substrate, comprising driving a processing machine according to any one of the preceding claims over a substrate and using the processing installation to pick up the fiber plants from the substrate, processing the fiber plants and then lay the processed fiber plants back on the substrate. A method according to claim 20, comprising picking up the fiber plants with a pick-up and turning installation from the substrate, subsequently turning the collected fiber plants over and placing the inverted fiber plants back on the substrate. 22. A method according to claim 20 or 21, comprising picking up the fiber plants from the substrate using a pick-up and winding installation, subsequently rolling up the picked fiber plants into a roll and placing the fiber plants rolled into a roll on the substrate again. .